Functional Classification of Super-Large Families of Enzymes Based on Substrate Binding Pocket Residues for Biocatalysis and Enzyme Engineering Applications.

Fernanda L Sirota,Zhi Li,Sebastian Maurer-Stroh,Birgit Eisenhaber,Frank Eisenhaber

doi:10.3389/fbioe.2021.701120

Abstract

Large enzyme families such as the groups of zinc-dependent alcohol dehydrogenases (ADHs), long chain alcohol oxidases (AOxs) or amine dehydrogenases (AmDHs) with, sometimes, more than one million sequences in the non-redundant protein database and hundreds of experimentally characterized enzymes are excellent cases for protein engineering efforts aimed at refining and modifying substrate specificity. Yet, the backside of this wealth of information is that it becomes technically difficult to rationally select optimal sequence targets as well as sequence positions for mutagenesis studies. In all three cases, we approach the problem by starting with a group of experimentally well studied family members (including those with available 3D structures) and creating a structure-guided multiple sequence alignment and a modified phylogenetic tree (aka binding site tree) based just on a selection of potential substrate binding residue positions derived from experimental information (not from the full-length sequence alignment). Hereupon, the remaining, mostly uncharacterized enzyme sequences can be mapped; as a trend, sequence grouping in the tree branches follows substrate specificity. We show that this information can be used in the target selection for protein engineering work to narrow down to single suitable sequences and just a few relevant candidate positions for directed evolution towards activity for desired organic compound substrates. We also demonstrate how to find the closest thermophile example in the dataset if the engineering is aimed at achieving most robust enzymes.

Highlights

Biocatalysis has gained importance both through methodological advances like enzyme engineering and directed evolution of enzymes towards new substrates (Arnold, 2019) as well as trends towards green chemical manufacturing (Dunn, 2012)
We describe the methodological approach in great detail for the group of zinc-dependent alcohol dehydrogenases (ADHs)
Few selected, very well studied sequences from C. parapsilosis and human origin (Gibbons and Hurley, 2004; Wang et al, 2014; Yamamoto et al, 1999) were analyzed and their alignment was manually curated based on the available structural information (Figure 1)

Summary

Introduction

Biocatalysis has gained importance both through methodological advances like enzyme engineering and directed evolution of enzymes towards new substrates (Arnold, 2019) as well as trends towards green chemical manufacturing (Dunn, 2012). Several large enzyme families are prominent candidates for biotechnology applications including enzyme engineering for certain substrate specificities because of the wide range of organic chemistry transformations that can be supported with them. Zinc-dependent alcohol dehydrogenases (ADHs; enzyme classification EC 1.1.1.1), long chain alcohol oxidases (AOxs; enzyme classification 1.1.3.20) and amino dehydrogenases (AmDHs, enzyme classification 1.4.1.20) are popular examples. Zinc-dependent ADHs are part of a very large family of enzymes (enzyme classification 1.1.1.*) catalyzing the reversible oxidation of diverse alcohols to aldehydes or ketones with the associated reduction of nicotinamide adenine dinucleotide (NAD+) or chemically similar co-factors. ADHs are extremely widespread; they have been identified in organisms ranging from prokaryotes to higher eukaryotes and have been studied for decades, in particular, the ones belonging to Saccharomyces cerevisiae (de Smidt et al, 2008), due to their importance and historical impact in fermentation

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Conclusion